Coupling the role of lipids to the conformational dynamics of the ABC transporter P-gp

Abstract

AbstractThe ATP-binding cassette (ABC) transporter P-glycoprotein (P-gp) is a multidrug efflux pump that is overexpressed in a variety of cancers and associated with the drug resistance phenomenon. P-gp structures were previously determined in detergent and in nanodiscs, in which different transmembrane helix conformations were found, “straight” and “kinked”, respectively, indicating a possible role of the lipid environment on the P-gp structural ensemble. Here, we investigate the dynamic conformational ensembles and protein-lipid interactions of the two human P-gp inward-open conformers (straight and kinked) employing all-atom molecular dynamics simulations in asymmetric multicomponent lipid bilayers that mimic the highly specialized hepatocyte membrane in which P-gp is expressed. The two conformers are found to differ in terms of the accessibility of the substrate cavity. The MD simulations show how cholesterol and different lipid species wedge, snorkel, and partially enter within the cavity of the straight P-gp conformer solved in detergent. However, the access to the cavity of kinked P-gp conformer solved in nanodiscs is restricted. Furthermore, the volume and dynamic fluctuations of the substrate cavity largely differ between the two P-gp structures, and are modulated by the presence (or absence) of cholesterol in the membrane and/or of ATP. From the mechanistic perspective, our findings indicate that the straight conformer likely precedes the kinked conformer in the functional working cycle of P-pg, with the latter conformation representing a post substrate-bound state. The inaccessibility of the main transmembrane cavity in the kinked conformer might be crucial in preventing substrate disengagement and transport withdrawal. Remarkably, in our unbiased MD simulations, one transmembrane portal helix (TM10) of the straight conformer underwent a spontaneous conformational transition to a kinked conformation, underlining the relevance of both conformations in a native phospholipid environment and revealing structural descriptors defining the transition between two P-gp conformers.